Smog

Smog is the chemical reaction of sunlight, nitrogen oxides (NOx), and volatile organic compounds (VOCs) in the atmosphere, which leaves airborne particles (particulate matter) and ground-level ozone (smog). Ground level ozone is an invisible gas made of three oxygen atoms (O3).

Nitrogen oxides are released by nitrogen and oxygen in the air reacting together under high temperature such as in the exhaust of fossil fuel-burning engines in cars, trucks, coal plants, and industrial manufacturing factories. VOCs are released from man-made sources such as gasoline (petrol), paints, solvents, pesticides, and biogenic sources, such as pine and citrus tree emissions.

The characteristic brown coloration for smog is due to the NOx in the photochemical smog.

Air pollutants in smog
This noxious mixture of air pollutants can include the following:
 * Aldehydes (RCHO)
 * Nitrogen oxides, such as nitrogen dioxide
 * Peroxyacyl nitrates (PAN)
 * Tropospheric (ground-level) ozone
 * Volatile organic compounds (VOCs)

All of these chemicals are usually highly reactive and oxidizing. Photochemical smog is therefore considered to be a problem of modern industrialization. It is present in all modern cities, but it is more common in cities with sunny, warm, dry climates and a large number of coal plants and motor vehicles. Because it travels with the wind, it can affect sparsely populated areas as well, leading to the EPA proposed Transport Rule.

2009 Environmental Science & Technology Study
A 2009 study, “Enhancement of Local Air Pollution by Urban CO2 Domes,” published in Environmental Science & Technology by Mark Z. Jacobson, found that domes of increased carbon dioxide concentrations – discovered to form above cities more than a decade ago – cause local temperature increases that in turn increase the amounts of local air pollutants, raising concentrations of health-damaging ground-level ozone as well as particulate matter in urban air.

According to Jacobson: "Warming increases water vapor, and both water vapor and higher temperatures increase ozone where the ozone is already high but have less effect where the ozone is low. Carbon dioxide domes over cities increase temperatures over the cities above and beyond the heat island effect, and these higher temperatures increase water vapor, and both higher water vapor and higher temperatures increase the rates of chemical air pollution production over cities relative to rural areas. The results suggest a causal nature of increased air pollution mortality due to increased carbon dioxide where the air pollution is already high. Thus, controlling CO2 emissions at the local level will reduce air pollution and the resulting air pollution mortality."

Jacobson’s estimates that “reducing local CO2 may reduce 300-1000 premature air pollution mortalities/yr in the U.S. and 50-100/yr in California, even if CO2 in adjacent regions is not controlled.”

2011 Union of Concerned Scientists Study
A 2011 study by the Union of Concerned Scientists "Climate Change and Your Health: Rising Temperatures, Worsening Ozone Pollution" projected future climate-induced temperature increases on the relationship between ozone concentrations and temperature to explore the potential “climate penalty on ozone pollution.”

Key findings included:


 * In 2020, the continental United States could pay an average of $5.4 billion (2008$) in health impact costs associated with the climate penalty on ozone. California and states in the Midwest and the Mid-Atlantic could be hit especially hard.
 * Higher ground-level ozone concentrations due to rising temperatures in 2020 could lead to an average of 2.8 million more occurrences of acute respiratory symptoms such as asthma attacks, shortness of breath, coughing, wheezing, and chest tightness. In 2050, that could rise to an average of 11.8 million additional occurrences.
 * Higher ozone concentrations due to rising temperatures could lead to an average of 3,700 more seniors and 1,400 more infants hospitalized for respiratory-related problems in 2020. In 2050, that could rise to 24,000 more seniors and 5,700 more infants hospitalized.

Respiratory
Ozone (smog) reacts chemically ("oxidizes") with internal body tissues, such as those in the lung, which the American Lung Association describes as a "sunburn" on the lungs. Ozone irritates and inflames the respiratory system at levels frequently found across the nation during the summer months. Breathing ozone may lead to:


 * shortness of breath, chest pain
 * inflammation of the lung lining, wheezing and coughing
 * increased risk of asthma attacks, need for medical treatment and for hospitalization for people with lung diseases, such as asthma or chronic obstructive pulmonary disease (COPD).
 * premature death

Children who grow up in areas of high ozone pollution may never develop their full lung capacity as adults. That can put them at greater risk of lung disease throughout their lives.

Cardiovascular
Recent research suggests that nitrogen oxides and particulate matter (PM2.5), along with other pollutants, are associated with hospital admissions for potentially fatal cardiac rhythm disturbances. Cities with high NO 2 concentrations have death rates four times higher than those with low NO 2 concentrations, suggesting a potential correlation. There are also cardiovascular effects from long-term air pollution exposure. Exposure to chronic air pollution over many years increases cardiovascular mortality, a correlation that remains significant even while controlling for other risk factors like smoking.

Nervous system
According to a 2009 Physicians for Social Responsibility report, the nervous system is also a target for coal pollution’s health effects, as the same mechanisms thought to mediate the effect of air pollutants on coronary arteries also apply to the arteries that nourish the brain. These include stimulation of the inflammatory response and oxidative stress, which can lead to stroke and other cerebral vascular disease.

Transport Rule
Acting under federal court order, the Obama administration proposed new air-quality rules on July 6, 2010, for coal-burning power plants, the Transport Rule. The pollutants being singled out in the new rule making — sulfur dioxide and nitrogen oxides — react in the atmosphere to form fine particulates and ground-level ozone (smog). They are easily carried by the wind and affect states and cities far downwind from the plants where they are produced. The proposed regulation, called the Transport Rule, would apply to power plants in 31 states east of the Rockies, with the exception of the Dakotas, Vermont, New Hampshire and Maine. The proposed rules will replace the EPA's 2005 Clean Air Interstate Rule.

Gina McCarthy, head of the EPA’s air and radiation office, said the new rules would reduce emissions of sulfur dioxide and nitrogen oxides by hundreds of thousands of tons a year and bring $120 billion in annual health benefits. Those benefits, Ms. McCarthy said, include preventing 14,000 to 36,000 premature deaths, 23,000 nonfatal heart attacks, 21,000 cases of acute bronchitis, 240,000 cases of aggravated asthma and 1.9 million missed school and work days. Additionally, the rule would substantially reduce unhealthy smog. The cost of compliance to utilities and other operators of power plants would be $2.8 billion a year, according to E.P.A. estimates.

The proposed regulation will require utilities operating coal-burning plants to install scrubbers and other technology to reduce emissions of the pollutants. Some companies may decide to retire older plants rather than invest in new control measures because other new rules under the Clean Air Act are expected in the coming years. The new rules do not address power plant emissions of carbon dioxide and five other pollutants that contribute to global warming. The Obama administration is moving forward with a plan to phase in regulation of such heat-trapping gases, a move that is being challenged in Congress and in the courts.

Ozone NAAQS
The Ozone National Ambient Air Quality Standards (NAAQS) refers to proposed EPA regulations on ground-level ozone, a primary ingredient in smog linked to respiratory illnesses. In January 2010, EPA Administrator Lisa Jackson said tightening the nation's air-quality standard for ozone was "long overdue," and would save an estimated 12,000 lives a year and yield health benefits up to $100 billion annually in 2020. The EPA proposed setting the standard at between 60 and 70 parts per billion, down from the current 75 ppb, by the end of 2010.

The EPA's proposal has the support of the American Lung Association and the American Medical Association, and is consistent with the recommendation of a 23-member panel of clean-air experts who advised the agency on the issue after reviewing more than 1,700 studies.

In December 2010, the EPA said that it will not decide until July 2011 whether to tighten the national air-quality standard for ozone. In a Dec. 8 written statement, the EPA said it would ask the panel of clean-air experts for "further interpretation" of the studies they relied upon in making their recommendation, so as to ensure the agency's final decision "is grounded in the best science."

In a written statement after the EPA delay, the American Lung Associations said it was "exploring legal options" aimed at requiring the EPA to make a decision on the issue. Based on EPA's own estimates, the group added, a six-month delay means an estimated 2,000 to 6,000 people "will lose their lives because they must breathe air pollution that would have been cleaned up if the EPA had met its most recent deadline of December 31, 2010."

EPA finds Clean Air Act benefits will add up to $2 trillion by 2020
According to an EPA report released in March 2011, "The Benefits and Costs of the Clean Air Act from 1990 to 2020", the annual dollar value of benefits of air quality improvements from 1990 to 2020 will reach a level of approximately $2.0 trillion in 2020. The benefits would be achieved as a result of Clean Air Act Amendment-related programs and regulatory compliance actions, estimated to cost approximately $65 billion by 2020.

Most of the benefits (about 85 percent) are attributable to reductions in premature mortality associated with reductions in ambient particulate matter: "as a result, we estimate that cleaner air will, by 2020, prevent 230,000 cases of premature mortality in that year" (Introduction). The remaining benefits are roughly equally divided among three categories of human health and environmental improvement: preventing premature mortality associated with ozone exposure; preventing morbidity, including acute myocardial infarctions and chronic bronchitis; and improving the quality of ecological resources and other aspects of the environment.

According to the report: "The very wide margin between estimated benefits and costs, and the results of our uncertainty analysis, suggest that it is extremely unlikely that the monetized benefits of the CAAA over the 1990 to 2020 period reasonably could be less than its costs, under any alternative set of assumptions we can conceive. Our central benefits estimate exceeds costs by a factor of more than 30 to one, and the high benefits estimate exceeds costs by 90 times. Even the low benefits estimate exceeds costs by about three to one."

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